Extended exergy-based fossil fuels resource accounting of China during 1980–2007

Available online at www.sciencedirect.com

Procedia Environmental Sciences 2 (2010) 1808–1817

International Society for Environmental Information Sciences 2010 Annual Conference (ISEIS)

Extended exergy-based fossil fuels resource accounting of China during 1980-2007 Jing DAI, Bin CHEN1* School of Environment, Beijing Normal University, Beijing 100875, China

Abstract Since the resources from environment are in short supply, it is necessary to alleviate the conflict between high-speed economic construction and limited resources in the Chinese society. This paper aims to analysis the variation of fossil fuels resource input into China during 1980-2007 based on extended exergy as an eco-centric metric. With the materials, energy, labor and capital quantified by exergy numeraire grounding on the second-law metric in view of ecological accounting, three indexes, i.e., total extended exergy requirement, extended exergy consumption intensity and extended exergy productivity of fossil fuels, are proposed to depict the contribution of four different production factors from economic, social and environmental aspects, respectively. All the comprehensive analysis based on extended exergy index may be helpful in uncovering the long-term resource depletion and promoting efficiency of the resource transformation in the social-economic-environmental system, thus providing holistic method and systematic view for the decision makers with respect to environmental management.

© 2010 Published by Elsevier Ltd. Keywords: extended exergy, ecological accounting, China

1. Introduction Highway greening is an important kind of land greening, which can be utilized in the restoration projects of damaged roadside ecosystem along highway. But with the rapid development of highway construction, the amount of greening wastes including litter, pruning and turf cutting litter and so on are continuously increasing,. In the past, the majority of greening wastes were treated as the solid wastes to landfill. However, this is very costly to collect, transport and fill the greening wasters, in addition to frequently-occurred incineration in autumn and winter. It is urgent to replace the traditional methods of greening waste treatment with innovative one to promote the recycling of greening wastes in highway construction projects. The depletion of non-renewable natural resources is very dangerous for the future existence of the mankind. The consumption of natural resources, and deleterious impacts on the environment should be evaluated in a unified criterion to describe and quantify the variation and direction in order to reflect the macrocosm situations in the process of energy and resource exploitation, especially taking into account humans involvements. At the same time, Corresponding author: Tel:86-10-5880-7368. E-mail address:[email protected](B.Chen).

1878-0296 © 2010 Published by Elsevier doi:10.1016/j.proenv.2010.10.192

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the thermodynamic evaluation of the environmental losses and natural resources has been considered as a useful tool in the field of natural resource accounting [1-3]. The concept of exergy, which is firstly proposed by Wall [4], is represented as the maximum work performed by a system in the process to get in equilibrium with its reference environment [5-7]. It (exergy) is considered to be the basic physical resource of social processes and the scientific unitary measurement of utility and scarcity. For a given system, exergy is defined as the maximal amount of work that can be extracted from the system in the process of reaching equilibrium with its local environment, chosen to have a direct bearing on the behavior of the system with respect to the time and length scales, depending on the observer’s objectives and knowledge [7-12], that is, ௧௢௧ ‫ܧ‬௫ ൌ ܶ଴ ሺܵ௘௤ െ ܵ ௧௢௧ ሻ (1) ௧௢௧ Where ܶ଴ is the temperature of the environment, ܵ௘௤ and ܵ ௧௢௧ are the entropies in thermodynamic equilibrium and at the given deviation from equilibrium, respectively, of the total system as a combination of the given system and the local environment. Therefore, exergy method, initially employed in thermal and thermo-chemical systems, has developed into a widely accepted approach for the account of large complex societal systems and different natural resource. It has also been adopted to reveal the characteristics of resource availability, buffering capacity and environmental impact for ecological system when preliminarily combined with the systems ecology [13]. The advantage of exergy based analysis compared with traditional energy analysis is that, exergy reflects the internal irreversibility of a system, which may depict the real thermodynamic conversion coefficient. Besides, exergy accounting provides a convenient way to unify and measure different types of materials, energy and information and evaluate the quality of the resources and degradation in the conversion. Usually, exergy is referred to standard chemistry exergy, which is a state function, to consider the previous pathways of exergy utilization. Szargut and his colleagues subsequently proposed cumulative exergy as the total consumption over time of the exergy of fossil resources connected with the fabrication of the considered production and the network of production processes [10], which view the ecological cost as the cumulative consumption of non-renewable exergy. Later, to extend the traditional exergy analysis based on exergy biophysics and labor theory of value, the concept of extended exergy, proposed by Sciubba, is to highlight the primary production factors, including labor, capital, exergy, necessary materials and environmental remediation [14-15], and firstly applied to the Italian society 1996 by Milia and Sciubba [16]. This approach is a systematic attempt to integrate into a unified coherent formalism both cumulative exergy consumption and thermo-economic methods, and constitutes a generalization of both, in that its framework allows for a direct quantitative comparison of non-energetic quantities like labor and environmental impact [14]. By using this method, “extended exergy accounting”, which includes in the exergy “balance” nonmaterial and nonenergetic production factors like labor, capital, and environmental remediation costs, it can be shown to provide a good measure of the amount of primary exergy resources “used up” in the life cycle of a material or immaterial commodity [17], which can indicate the comprehensive statement of socially necessary, economically feasible and environmentally cost. Compared with traditional exergy analysis, the advantage of extended exergy analysis (EEA) is that, it allows for the calculation of the conversion coefficient of the domestic sector by considering the working hours as its product [18] . As extended exergy is a path function, it is different from the state function of standard chemical exergy. Therefore, it can be concluded that EEA results are more reasonable and directive for the resource policy constitution of the whole country. As mentioned, the EEA is an integration of life cycle analysis, classical exergy analysis, cumulative exergy analysis, emergy analysis, and embodied; energy analysis at the base of the classical exergy analysis, which is more suitable to act as the second-law efficiency metric. Society extended exergy analysis is considered as an effective method to reveal the energy quality and degradation in the resource conversion process at the national level. The comparison of social resource accounting among different societies by using diverse index can not only obtain information about diagnosis of production conversion coefficient, assessment of environment impact and ecological dysfunction [19-22], but also reveal the intrinsic societal resource utilization structure and its temporal and spatial allocation. Generally speaking, fossil fuels analyses are conducted regularly by the official statistical agencies and included in the official statistical reports. Usually, these statistical analyses tend to be summarized and quantified in terms of monetary values or weight analysis. However, in view of the relation to future usefulness of fossil fuels and the irreversibility associated with the use, the growing discomfort in the processes of evaluating resource where money

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or weight is the common metric is lack of exactitude, which lead us to use extended exergy analysis as the tool to revalue the synthetic consumption of fossil resource in China with a view to natural, economical and social aspects. This study is primarily a case study about fossil fuels consumption where the EEA is employed within the mainland of China. It may also contribute to the development of the method and to the discussion of some implications by using it. 2. Methodology and data used 2.1 Method(system boundary) By Sciubba’s method of EEA, extended exergy (EE) values are assigned to labor and capital fluxes in addition to thermomechanical and chemical exergy values [20]. The calculation of EE value is formulated by Sciubba as follow, ‫ ܧܧ‬ൌ ‫ ܥܧܥ‬൅ ‫ܧ‬஼ ൅ ‫ܧ‬ௐ ൅ ‫ܧ‬ோ (2) where ‫ ܥܧܥ‬represents the cumulative exergy consumption, ‫ܧ‬஼௔௣௜௧௔௟ (‫ܧ‬஼ ) represents the exergy equivalent of monetary flows, ‫ܧ‬௅௔௕௢௥ (‫ܧ‬ௐ ) is the exergy equivalent of human labor, and ‫ܧ‬ோ stands for the environmental clean-up or remediation cost. Generally speaking, ‫ܧ‬஼ , ‫ܧ‬ௐ and ‫ܧ‬ோ all are path functions, so the extended exergy in fact is a path function, which is different from the state function of standard chemical exergy. In the reference (Milia and Sciubba, 2006), the accounting value of ‫ܧ‬஼ and ‫ܧ‬௅ are precisely given, respectively, ‫ܧ‬஼ ൌ ‫ܥ‬ ‫ܧ‬ௐ ൌ ݊

ா೔೙

(3)

஼ೝ೐೑ ா೔೙

(4)

௡೟೚೟

where ‫ܧ‬௜௡ is the exergy influx to the society, ‫ ܥ‬is the monetary flux in a relevant currency and ‫ܥ‬௥௘௙ is a proper measure of the “monetary flux”, in which the choice of ‫ܥ‬௥௘௙ is considered to be arbitrary and depended on the conditions in different countries. Besides ݊ is the flux of work-hours into a sector, and ݊௧௢௧ is the total amount of work-hours. To different study objects, ‫ܧ‬ோ is sometimes contained in ‫ ܥܧܥ‬as a part of cumulative exergy consumption in the aspect of environmental cost. In this research, by overall consideration of the study object and the case country, we modified that EE accounting is divided into three parts, the exergy of fossil fuels, capital exergy and labor exergy. Meanwhile, the exergy part can be calculated by exergy factors and the conversion efficiency from Kotas [23] in Table 1; gross domestic product (GDP) is chosen as ‫ܥ‬௥௘௙ due to the assumption that the equivalent exergy of GDP was equal to the exergy values of energy carriers and materials; ‫ ܥ‬, refers to the capital flux into fossil industry, is corresponding to yearly input of capital asserts. Suppose that all the people have a same work-hours in different professions, people proportion of those who work in the field of fossil resource to total working people can stand for the ratio of ݊ to ݊௧௢௧ . Table 1 Exergy factors of fossil fuels Fuel form

Exergy factors

Exergy (J/t or J/m3)

Coal

1.06

2.79h1010

Crude oil

1.08

4.52h1010

Natural gas

1.04

4.05h107

Major natural resources entering the economic production mainly include three parts, they are mineral resources, biomass resources, and water resources. To be concrete, in this study, ‫ܧ‬௜௡ , total natural exergy influx, contains fossil fuels, metal minerals, nonmetallic minerals, agriculture, forestry, livestock, fishery, biomass fuels, chemical water exergy and waterpower. The value of ‫ܧ‬௜௡ in 1980-2002 comes from the references of Chen [24-27]. By analyzing the ratio of fossil fuels exergy to total natural resource exergy during the year from 1980 to 2002, the

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average value was 0.63. Therefore, ‫ܧ‬௜௡ in 2003 to 2007 can be estimated based on the ratio and yearly fossil fuels exergy. 2.2 System boundary In this study, the chosen object referred to the consumption of fossil fuels, which was one kind of common natural resource, and the research boundary was limited within the region of mainland China except Tibet, because of its unavailable data in long time series. The detailed numerical values would be listed in the part of Results and Discussion. 2.3 Date collection All the data sources available are acquired from standard yearbooks and publications compiled by the central government and its subordinate ministries, such as Energy Statistical Yearbooks, Statistical Yearbooks of China and so on. 3. Results The social basic situation, such as population, GDP, and extended exergy based on natural, economic and social parts from 1980 to 2007 are listed in Table 2. It demonstrated that, the total exergy consumption on three kinds of fossil fuels was increasing persistently, the growing trend was gentle durning 1980 to 2002, while greatly run up in the rear five years. This diversification indicated energy using speed on fossil resources was in accelerated depleted situation, especially in recent five years, which was agree with economic development and social construction by leaps and bounds in China. From Table 2, and Fig.1, we can obtain that, the capital and labor exergy proportion in extended exergy in the field of fossil fuels was comparatively low, but from 2002, this ratio began to rise, which implied non-natural elements in available energy accounting became more important than ever before. In Fig.1, there is an amphicoelous temporal point in the year of 1998 and 1999, the reason of low total natural exergy consumption can be attributed to the readjustments of the industrial structure as well as the sustainable developing pattern proposed and carried out during the eighth and ninth five-year plan in China. Meanwhile, the subsequently accelerated growth in extended exergy consumption, partly due to extensive social construction closely depending on energy input, besides, labor and capital devotion plays a more important role in extended exergy accounting, especially began from the year of 2002. This conversion can tell that non-natural exergy, e.g. technical, labor and capital input have been attached importance in recent years, and had much influence by technical improvements and capital circulation. Table 2 Analysis of extended exergy in fossil fuels accounting in China (1980-2007)

Year

Population 4

GDP 8

Total

exergy

of

Capital exergy

Labor

extended exergy

(10 )

(10 RMB˅

fossil fuels (J)

(J)

exergy(J)

(J)

1980

98705

4470

2.20E+19

4.60E+17

2.63E+17

2.22E+19

1985

104532

8537

2.90E+19

5.51E+17

3.52E+17

2.99E+19

1990

114333

17686

3.56E+19

6.42E+17

4.28E+17

3.67E+19

1991

115823

21618

3.61E+19

6.41E+17

4.45E+17

3.72E+19

1992

117171

26638

3.72E+19

6.49E+17

4.37E+17

3.83E+19

1993

118517

34634

3.87E+19

6.02E+17

4.67E+17

3.97E+19

1994

119850

46759

4.04E+19

5.14E+17

4.65E+17

4.14E+19

1995

121121

58478

4.54E+19

5.07E+17

5.21E+17

4.65E+19

1996

122389

68594

4.61E+19

4.93E+17

4.99E+17

4.71E+19

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1997

123626

74463

4.55E+19

5.87E+17

4.74E+17

4.66E+19

1998

124810

78345

3.31E+19

3.48E+17

2.91E+17

3.38E+19

1999

125909

81911

3.35E+19

3.09E+17

2.83E+17

3.41E+19

2000

126743

99214

4.62E+19

4.53E+17

3.59E+17

4.71E+19

2001

127627

109654

5.14E+19

4.91E+17

3.67E+17

5.22E+19

2002

128453

120333

5.01E+19

4.42E+17

3.40E+17

5.09E+19

2003

129227

135822

5.85E+19

1.21E+18

3.45E+17

6E+19

2004

129988

159877

6.85E+19

1.63E+18

4.10E+17

7.06E+19

2005

130756

183084

7.57E+19

2.35E+18

4.56E+17

7.85E+19

2006

131448

210871

8.24E+19

2.90E+18

5.15E+17

8.58E+19

2007

132129

249529

8.89E+19

3.32E+18

5.58E+17

9.28E+19

Fig.1 The variation trend of total exergy and extended exergy in fossil fuels accounting in China (1980-2007)

Two indexes, extended exergy consumption intensity (EECI) and extended exergy productivity (EEP), are chosen in this research to present the interaction between EE consumption and social system. EECI is an indicator that can reveal the level of per capita resource which can reflect the personal access to fossil resource in China. EEP, an economic value produced by unit natural substance, is a key indicator in measuring the inter connection between available extended exergy resource and social economy. This index can tell the transfer ability from row material into monetary value, which usually represents the efficiency of resource consumption. The statistics of both two which calculated from 1980 to 2007 are showed in the following Table 3 to depict the total variation trend in China. On the whole, EECI kept sustained and rapid growth, with its value 3.12 times in 2007 than that in 1980; and EEP declined noticeably, which was less than 8% in 2007 compared with that in 1980. Both of the transformations indicated expansion of per capita share on available fossil energy, as well as the efficiency improvement of power production on unit currency. Table 3 Extended exergy consumption intensity consumption, extended exergy productivity of fossil fuels consumption in China during 1980-2007

Year

exchange rate for US dollar to RME

Year

exchange rate for US dollar to RME

Year

exchange rate for US dollar to RME

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1980

1.5

1990

4.8

2000

8.3

1981

1.7

1991

5.3

2001

8.3

1982

1.9

1992

5.5

2002

8.3

1983

2.0

1993

5.8

2003

8.3

1984

2.3

1994

8.6

2004

8.3

1985

2.9

1995

8.4

2005

8.1

1986

3.5

1996

8.3

2006

7.8

1987

3.7

1997

8.3

2007

7.3

1988

3.7

1998

8.3

1989

3.8

1999

8.3

In Fig. 2, the trendline of increasing EECI can be divided into three phases, the first part (1980-1997) was in stable growth, the second part (1998-2001) was fluctuate adjustment time, and the last one (2002-2007) was striking growth period. This developing trend was conformed to economic laws, domestic and international social background. Fome1998, China successively suffered summer flooding along the Yangtse River, and the influence of Asia financial crisis in social and economic aspectsˈas well as the prominent readjustments of the industrial structure. Except for natural and social criticism, industrial restructuring and deeply implement of the transconformation from planned economy to market economy were also important elements in effecting economical construction, which finally lead to an undulation era in resource consumption and EECI. Wholly speaking, the increasing EECI implied that a great demand beyond necessaries had become life pursue after China progressively entering into affluent society. After the optimization of industrial structure since enter into 21th century, the enormous requirements for private car, energy-consumption electronic products made life quality improve deeply on the one hand, and on the other hand extremely aggravated fossil resources depletion. The only solution to avoid energy crisis, especially for non-renewable energy, is to elevate utilization efficiency and attempt new renewable energy. In addition, China is the most populous developing country, its contradiction between large energy-needed population and low per capita energy possession is always restricting the whole national development in social and economic fields.

Fig.2 Extended exergy consumption intensity (J/person) in China during 1980-2007

The following Fig.3(1) showed the decreasing trend of extended exergy productivity (EEP) based on RMB, in the first stage from 1980 to 1998, the value of EEP fell obviously, which was about one in tenth in 1998 than that in 1980; in the second stage from 1999 to 2007, EEP had become in a comparative stable state. But in Fig.3(2), EEP based on U.S. dollar, was firstly in appreciable fluctuations with a decreasing tendency, and then inappreciable decline. It is observed that EEP is falling basically, which means a gradually improving transfer ability from row material into monetary value as mentioned before. Whereas, different currency and its stability can work on the

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value of this indicator greatly, only international strong currencies can safeguard an authentic and convincing evaluation of worldwide scope or applicability.

Fig.3(1) Extended exergy productivity (J/RMB) of fossil fuels consumption in China (1980-2007)

Fig.3(2) Extended exergy productivity (J/$) of fossil fuels consumption in China (1980-2007)

4. Conclusion In country level, extended exergy of fossil fuel in Mainland of China was always increasing from 1980-2007, especially accelerated after entering into the 21 century. The changing of extended- exergy on natural resource that basically agree with the trend of economic growth and new situation of social develop can clearly proclaim that natural energy is particularly important element in the process for one country’s development. Furthermore, the rising degree of extended exergy was more distinctive than that of exergy, so the significance of capital and manpower input became stronger than ever before, and should not be omitted anymore, besides, we should devote much non material object instead of natural resource to relief energy depletion. Both increasing EECI and decreasing EEP demonstrate a positive conversion in transferring quantity and efficiency from material energy to economic output. But in order to develop in a sustainable pattern, production sectors and administration sections should devote more efforts on bettering workpiece ratio other than go in for extensive production with massive resource consuming. 5. Analysis and discussion It can be concluded that EEA results are more reasonable and directive for the resource policy constitution of the

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whole country. As mentioned, the EEA is an integration of life cycle analysis, classical exergy analysis, cumulative exerg analysis, emerg analysis, and embodied energy analysis and also this analysis is more suitable to act as a second-law efficiency metric.

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Acknowledgements This study was supported by the Program for New Century Excellent Talents in University (NCET-09-0226), National High Technology Research and Development Program of China (No., 2009AA06A419), Key Program of National Natural Science Foundation (No., 50939001), National Natural Science Foundation of China (Nos., 40701023, 40901269, 40871056), National Key Technologies R&D Program (No., 2007BAC28B03), and State Key Basic Research and Development Plan of China (973 Plan, No., 2005CB-724204). References [1] Frangopoulos, C. 1992. Introduction to environomic analysis and optimization of energy-intensive systems. ASME, NEW YORK, NY(USA,1992, 231-239. [2] Sciubba E. A novel exergetic costing method for determining the optimal allocation of scarce resources. Proceedings of Seminar “Contemporary Problems of Thermal Engineering, 1998. [3] Szargut J, Ziebik A. and Stanek W. Depletion of the non-renewable natural exergy resources as a measure of the ecological cost. Energy Conversion and Management”, 2002, 43:1149-1163. [4] Wall G. Exergy: A useful concept within resource accounting. Gteborg: Institute of Theoretical Physics, Chalmers University of Technology & University of G teborg.1977. [5] Wall G. Exergy conversion in the Swedish society. Resources and Energy, 1987, 9:55-73. [6] Wall G. Exergy conversion in the Japanese society. Energy, 1990, 15:435-444. [7] Chen GQ. Exergy consumption of the earth. Ecological Modelling, 2005, 184:363-380. [8] Szargut J, Dziedziniewicz C. Energie utilisable des substances chimiques inorganiques. Entropie,1971, 40:14-23. [9] Szargut J. International progress in second law analysis. Energy,1980, 5:709-718. [10] Morris D R, Szargut J. Standard chemical exergy of some elements and compounds on the planet earth. Energy, 1986, 11:733-755. [11] Szargut J T. Optimization of the design parameters aiming at the minimization of the depletion of non-renewable resources. Energy, 2004, 29:2161-2169. [12] Chen G Q. Scarcity of exergy and ecological evaluation based on embodied exergy. Communications in Nonlinear Science and Numerical Simulation, 2006, 11:531-552. [13] Cai Z F, Yang Q, Zhang B, et al.. Water resources in unified accounting for natural resources. Communications in Nonlinear Science and Numerical Simulation, 2009, 14:3693-3704. [14] Sciubba E. Beyond thermoeconomics? The concept of Extended Exergy Accounting and its application to the analysis and design of thermal systems. Exergy, 2001, 1:68-84. [15] Sciubba E, Cutler J C. Exergoeconomics. Encyclopedia of Energy. Elsevier, New York, 2004, 577-591. [16] Milia D, Sciubba E. Exergy-based lumped simulation of complex systems: an interactive analysis tool. Energy, 2006, 31:100-111. [17] Sciubba E, Sven Erik J and Brian F. Exergy Destruction as an Ecological Indicator. Encyclopedia of Ecology. Academic Press, Oxford, 2008, 1510-1522. [18] Chen G Q, Chen B. Extended exergy analysis of the Chinese society. Energy, 2009, 34:1127-1144. [19] Reistad G. Available energy conversion and utilization in the United States. ASME Transactions Series Journal of Engineering Power, 1975, 97:429-434. [20] Ertesvag I S. Energy, exergy, and extended exergy analysis of the Norwegian society 2000. Energy, 2005, 30:649-675. [21] Chen B, Chen G Q. Exergy analysis for resource conversion of the Chinese Society 1993 under the material product system. Energy, 2006, 31:1115-1150. [22] Chen B, Chen G Q, Yang Z F. Exergy-based resource accounting for China. Ecological Modelling, 2006, 196:313-328. [23] Kotas T. The Exergy Method of Thermal Plant Analysis, Butterworths, London, 1985. [24]Chen G, Chen B. Resource analysis of the Chinese society 1980–2002 based on exergy—Part 1: Fossil fuels and energy minerals. Energy policy, 2007, 35:2038-2050. [25] Chen B, Chen G. Resource analysis of the Chinese society 1980–2002 based on exergy—Part 2: Renewable energy sources and forest. Energy policy, 2007, 35:2051-2064. [26] Chen B, Chen G. Resource analysis of the Chinese society 1980–2002 based on exergy—Part 4: Fishery and rangeland. Energy policy, 2007, 35:2079-2086.

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